MEMS device with two axes comb drive actuators

ABSTRACT

In certain embodiments, a MEMS actuator is provided comprising a frame and a movable structure coupled to the frame. A vertical comb drive is provided between the frame and the movable structure to actuate the movable structure.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of the following U.S. Patent Applications, all herein incorporated by reference in their entireties:

-   -   Provisional Application Ser. No. 60/340,318, filed on Dec. 13,         2001, by Gritters et al., entitled MEMS VERTICAL COMB-DRIVE         ACTUATOR;     -   Provisional Application Ser. No. 60/340,677, filed on Dec. 13,         2001, by Gritters et al., entitled METHOD FOR FABRICATING         VERTICALLY SELF-ALIGNED ELECTRICALLY-ISOLATED MEMS COMB DRIVE         ACTUATOR;     -   Application Ser. No. 10/189,234, filed Jul. 2, 2002 now         abandoned, by John Gritters, entitled MEMS JUNCTION         ELECTROSTATIC VERTICAL COMB VERTICAL COMB DRIVE AND METHOD OF         FABRICATION;     -   Application Ser. No. 10/191,041, filed on Jul. 2, 2002 now         abandoned, by Gritters et al., entitled MEMS VERTICAL COMB DRIVE         HAVING STARTER TOOTH; and     -   Application Ser. No. 10/190,083, filed Jul. 2, 2002 now         abandoned, by Gritters, et al. entitled MEMS VERTICAL COMB DRIVE         ACTUATOR HAVING LINEARIZED DRIVE AND METHOD FOR SAME.

BACKGROUND

Microelectromechanical systems (MEMS), which are made up of several micromachined electrical-mechanical structures, have a size typically on a millimeter scale or smaller. These micromachined structures are used to produce MEMS devices that are used in a wide variety of applications including, for example, sensing, electrical and optical switching, and micromachinery (such as robotics and motors). MEMS devices utilize both the mechanical and electrical attributes of a material to achieve desired results. Because of their small size, MEMS devices may be fabricated using semiconductor processing methods and other microfabrication techniques, such as thin-film processing and photolithography.

MEMS technology allows movable microelectromechanical parts to be integrated with micro-optical structures to create MEMS optical devices. These MEMS optical devices may be mass produced at low cost using batch fabrication processes. Moreover, because of their small size and low mass, highly efficient optical devices may be produced with optical MEMS technology. By way of example, applications of optical MEMS technology include optical switches, optical data storage, optical scanners and fiber optic sensors.

One example of a MEMS optical device is a planar all-optical switch. An all-optical switch is capable of switching optical signals between input and output channels without the need for opto-electrical signal conversion. In one embodiment, the all-optical switch includes a MEMS structure having a mirrored surfaced mounted on a movable structure and an actuator for providing force to move the mirrored surface. Using the actuator the mirrored surface can be moved to selectively intercept the path of an optical signal. By selectively intercepting the optical signal, it may be directed to a desired output optical fiber. Such optical switches typically move the mirrored surface about a single axis and utilize only two switch positions, to either intercept or not intercept the optical signal.

In another type of all optical switch, two axes actuators are used. Two-axes actuators are capable of rotating the mirrored surface around two substantially orthogonal axes such that the mirror is capable of being positioned in several different positions. Conventional two-axes optical devices use actuation that includes pads located under the mirrored surface for developing an electrostatic force. In order to position the mirrored surface, the pads are charged such that the mirrored surface is attracted to the charged pads. By selectively positioning the mirror, an optical signal may be directed to one of the many locations.

One problem with this pad-type actuator, however, is that an electric force is generated across a relatively large gap between the pad and the backside of the mirror. This gap exists because the pads are located under the mirrored surface and must allow room for mirror displacement. This large gap effectively decreases the amount of force available to move the mirror, resulting in an increased force requirement, necessitating an increase in system voltage and power to drive the actuator pads. Moreover, with pad-type actuators snap-down can occur due to electrostatic instability occurring because the force from the pad can increase faster that the restoring force from the spring.

Another problem with the above discussed pad-type actuator is that there is no independent control of movement around the two axes in which the mirrored surface rotates. Instead, movement around the two axes is coupled as movement of the mirror along one axis changes the gap distance for the pads under different portions of the mirror. This coupled movement severely limits the angle of scan that can be achieved by the mirror. An additional problem with the coupled movement is that disturbances are harder to correct because damping must occur on both axes. Damping must be applied to the non-disturbed axis as well, because movement around the axes are not independent of each other. Therefore, there exist a need for a manufacturable improved two-axes actuator.

SUMMARY

In certain embodiments, a MEMS actuator is provided comprising a frame and a movable structure coupled to the frame. A vertical comb drive is provided between the frame and the movable structure to actuate the movable structure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a top view of an embodiment of a two-axes torsional comb-drive actuator in accordance with the present invention.

FIG. 2 is an isometric view illustrating an embodiment of the two-axes MEMS torsional comb-drive actuator in accordance with the present invention.

FIG. 2A is a plan view of an upper layer of the MEMS actuator shown in FIG. 2.

FIG. 2B is a plan view of an intermediate layer of the MEMS actuator shown in FIG. 2.

FIG. 3A is a partial cross-sectional view of the MEMS actuator shown in FIG. 2 taken through the line A-A.

FIG. 3B is a partial cross-sectional view of the MEMS actuator shown in FIG. 2 taken through the line A-A and illustrates the movement of the comb drive.

FIGS. 4A-H illustrate a possible implementation of a self-aligned process in accordance with the present invention for defining a comb structure.

FIGS. 5A-G illustrate a possible implementation of the bulk protective material process and the self-dicing process in accordance with the present invention.

FIG. 6 shows a simplified illustration of single axis actuator.

FIG. 7 shows a simplified illustration of single axis actuator.

FIG. 8 shows a simplified illustration of a single axis diving board type actuator.

FIG. 9 shows a simplified illustration of a piston type actuator.

FIG. 10 shows a simplified illustration of a multiple diving board actuator.

FIGS. 11-14 show simplified illustrations of a two axes actuators.

FIG. 15 shows a simplified illustration of a double angle, co-axial comb drive actuator.

FIG. 16 shows a simplified illustration of a triple angle, co-axial comb drive actuator.

FIGS. 17 & 18 show simplified illustrations of two axes, single direction actuators.

FIG. 19 shows a simplified illustration of a segmented actuator.

FIG. 20 shows a simplified illustration of a vertical comb drive device having a vertical movable structure.

FIG. 21 shows a simplified illustration of a vertical comb drive device having a vertical movable structure.

DESCRIPTION I. Structural Overview

Although some of the embodiments of the present invention are discussed in terms of optical switching and mirror structures, it is understood and contemplated that the present invention has application in a variety of fields where the use of MEMS technology is desirable. For example, certain embodiments of the present invention may be embodied in electrical devices such as relays and tunable RF filters, in microfluidic devices such as pumps and valves, in actuating and/or scanning devices, or in other devices such as sensors, displays, readers, or equipment such as cameras or medical devices, etc.

The MEMS comb drive actuator of certain embodiments of the present invention allow a wide range of movement and/or accurate positioning of a structure. This allows the actuator to be used in several different applications where such wide range of movement and/or positioning is needed.

FIG. 1 is a top view of a simplified example of a MEMS torsional comb drive actuator 1 in accordance with an embodiment of the present invention. The MEMS actuator 1 includes an outer fixed frame structure 5 and a movable central structure 10. A movable frame structure 20 is located between the movable central structure 10 and the outer fixed frame structure 5. The movable frame structure 20 is coupled to the fixed frame structure 5 and to the movable central structure 10 so as to allow movement about a first axis (labeled FIRST AXIS in FIG. 1) of the movable central structure 10, independent of the movable frame structure 20. Further, the movable frame structure 20 is coupled to the movable central structure 10 so that it accompanies the movement of the movable central structure 10 about a second axis (labeled SECOND AXIS in FIG. 1). First axis torsional support members 25 couple the movable central structure 10 to the movable frame structure 20. Second axis torsional support members 30 couple the movable frame structure 20 to the outer fixed frame structure 5.

The two-axes MEMS actuator 1 includes comb drives that provide the electrostatic coupling needed for movement. A first axis comb drive system 35 is located near the first axis torsional support members 25. This first axis comb drive system 35 provides movement of the movable central structure 10 around the first axis. A second axis comb drive system 40 is located near the second axis torsional support members 30. The second axis comb drive system 40 provides movement of the movable frame structure 20 around the second axis. In one embodiment, the first axis comb drive system 35 includes two comb drives, one on either side of the first axis torsional support member 25. In addition, the second axis comb drive system 40 can have two comb drives, one located on either side of the second axis torsional support member 30.

In this embodiment, application of a voltage at the V3 and/or V4 terminals will actuate the central movable structure 10 about the first axis. Application of voltage at the V3 terminal supplies actuation voltage to the comb drives 35 c and 35 d. Application of voltage at the V4 terminal supplies actuation voltage to the comb drives 35 a and 35 b.

Application of a voltage at the V1 terminals and/or at the V2 terminals actuates the comb drives about the second axis. Application of voltage to the V1 terminals supplies voltage to the comb drives 40 c and 40 d. Application of voltage to the V2 terminals supplies actuation voltage to the comb drives 40 a and 40 b.

It should be noted that it is possible to operate the actuator 1 using one set of the V1 supplied combs 40 c or 40 d, and one of the set of V2 supplied comb 40 a or 40 b. Likewise, it is possible to operate the actuator 1 using only one of the set of V3 supplied combs 35 c or 35 d, and one of the set of V4 supplied combs 35 a or 35 b.

FIG. 2 is an isometric view illustrating an example of a two-axes MEMS torsional comb-drive actuator 100 in accordance with certain embodiments of the present invention. The MEMS actuator 100 includes an outer fixed frame structure 105 and a movable central structure 110. A mirrored surface 115 may be located on the movable central structure 110. In other embodiments, other devices or structures such as a light source, lens, sensors (magnetic, optical, acceleration, or the like), a probe microscopy element, an electron/particle beam steering element, an optical diffraction grating, vertical mirror or other vertical element, or the like may be located on the movable central structure 110. Although shown on a top facing surface of the movable central structure 110, it is possible to locate the mirror or other device on the other side of the movable central structure 110.

Movable frame structure 120 is located between the movable central structure 110 and the outer fixed frame structure 105. The movable frame structure 120 is coupled to the fixed frame structure 105 and to the movable central structure 110 so as to allow movement about a first axis (labeled FIRST AXIS in FIG. 2) of the movable central structure 110, independent of the movable frame structure 120. Further, the movable frame structure 120 is coupled to the movable central structure 110 so that it accompanies the movement of the movable central structure 110 about a second axis (labeled SECOND AXIS in FIG. 1).

First axis torsional support members 125 defining a first axis 126, passing through shaft portions 126 a and 126 b shown in FIG. 2B, couple the movable central structure 110 to the movable frame structure 120. Second axis torsional support members 130 defining a second axis 131, passing through shaft portions 130 a and 130 b shown in FIG. 2B, couple the movable frame structure 120 to the outer fixed frame structure 105. Although the first and second axes are shown orthogonal in this embodiment, other arrangements are possible.

As discussed further below, the first axis torsional support members 125 include a single support member on opposite sides of the movable central structure 110, while the second axis torsional support members 130 can include two support members on each side of the movable frame structure 120. Each of these torsional support members is aligned with their respective axes. The torsional support members 125 and 130 are flexible about their respective axis. Further, they may provide a restoring force when torsionally deformed along their axis, to apply force to the support member toward its original position.

The movable frame structure 120 has an upper portion 120 u and a lower portion 120 i separated by an insulator portion (not shown). The upper portion 120 u of the movable frame 120 is segmented into two segments 123 and 124. The segment 123 forms part of first axis comb drive portions 135 a and 135 b. The first axis comb drive portions 135 a and 135 b are attached near the ends of the segment 123 adjacent the first axis. The segment 124 forms part of first axis comb drive portions 135 c and 135 d. These first axis comb drive portions 135 c and 135 d are attached near the ends of the segment 124 adjacent the first axis, opposite first axis comb drive portions 135 a and 135 b, respectively. In this embodiment, the comb drives portions 135 a, 135 b, 135 c, and 135 d form the first axis comb drive system 135. Other embodiments are possible where the first axis comb drive system 135 may include less than all of these comb drive portions 135 a, 135 b, 135 c, and 135 d.

The MEMS actuator 100 can be fabricated from a layered structure 600, shown in FIG. 4A. In particular, in the embodiment of FIG. 2, the MEMS actuator 100 includes a lower layer 180, which may be a substrate-type layer of silicon or other material such as glass, sapphire, or other substrate material. The MEMS actuator 100 also includes an intermediate layer 182 of conductive micromachinable material, which may be metal, doped semiconductor material, or other conductive material. Over the intermediate layer 182 is an upper layer 184 of conductive micromachinable material, which may be metal, semiconductor material, or other conductive material. Thus, in some embodiments, the MEMS actuator 100 may include three layers 180, 182, and 184 of semiconductor material.

Between the lower layer 180 and the intermediate layer 182 is a first insulator layer (not shown), and between the intermediate layer 182 and the upper layer 184 is a second insulator layer (not shown). The first and second insulator layers 180 and 182 may be dielectric material such as oxide. In some embodiments, the lower layer 180, intermediate layer 182, and the upper layer 184 (and corresponding structures) can be isolated using junction isolation rather than insulator layers. As such, appropriate doping and biasing of structures can be employed to provide electrical isolation between structure layers.

Isolation channels 186, 190, 187, 191 are formed into the upper layer 184. In particular, isolation channels 186 and 187 are formed in the upper layer 184 such that the upper layer 184 has a first isolated area 189. Isolated area 189 allows electrical power to be applied to comb drives 140 a and 140 b. Similarly, isolation channels 190 and 191 formed in the upper layer 184 so that the upper layer 184 has a second isolated area 194. The second isolated area 194 allow electrical power to be applied to comb drives 140 c and 140 d.

The isolation channels 186 and 190 also define a third isolated area 195 that allows electrical power to be supplied to the comb drives 135 a and 135 b coupled to the segment 123. The isolation channels 187 and 191 define a fourth isolated area 196 that allows electrical power to be supplied to the comb drives 135 c and 135 d on the segment 124. The isolated areas 189, 194, 195, and 196 allow electrical power to independently be supplied to the comb drive systems 135 and 140.

As discussed above, isolated areas 195 and 196 allow application of electrical power to the first axis comb drive system 135. For example, electrical power can be provided to the first axis comb drives 135 a and 135 b from the third isolated area 195. Thus, electrical power may be applied at the third isolated area 195 and delivered through an associated one of the second axis torsional support members 130, through the segment 123 of the upper portion 120 u of the movable frame 120, to the first axis comb drive portions 135 a and 135 b.

Similarly, electrical power is supplied to the first axis comb drives 135 c and 135 d through the fourth isolated area 196. Thus, electrical power applied at the fourth isolated area 196 is delivered through the associated one of the second axis torsional support members 130, through the segment 124, to the comb drives 135 c and 135 d.

The isolated areas 189, 194, 195 and 196 may also be used in conjunction with their respective comb drives to capacitively sense orientation of the movable structure 110 and its associated mirror 115. Position is determined by determining capacitance in each of the comb drives. For example, a comb drive on one side of an axis can be used to provide movement of the actuator around the axis, while a comb drive on the other side of the axis capacitively senses position.

A bond pad 198 can be created on the intermediate layer 182 so that electrical potential can be applied to the intermediate layer 182. An opening formed in the upper layer 184 to allow electrical contact the intermediate layer 182. The bond pad 198 is used to keep the entire bottom layer 182 at the same potential (such as ground).

FIG. 2A is a plan view of the upper layer 184 of the MEMS actuator shown in FIG. 2. Referring to FIGS. 2 and 2A, the fixed frame structure 105 is divided into separate electrically isolated areas 189, 194, 195, and 196 by the isolation channels 186, 187, 190, 191. More specifically, isolation channel 186 and the isolation channel 187 that forms the first isolated area 189. The first isolated area 189 allows coupling of electrical power to upper portions 140 au and 140 bu the comb drives 140 a and 140 b. Furthermore, isolation channels 190 and 191 form the second isolated area 194. The second isolated area 194 allows coupling of electrical power to upper portions 140 cu and 140 du of comb drives 140 c and 140 d. The isolation channel 186 and the isolation channel 190 serve to electrically isolate the third isolated area 195 from the first isolated area 189 and from the second isolated area 194. This allows electrical power to be applied at the third isolated area 195 for coupling to upper portions 135 au and 135 bu of the comb drives 135 a and 135 b. The isolation channels 187 and 191 electrically isolate the fourth isolated area 196 from the first isolated area 189 and from the second isolated area 194. The fourth isolated area 196 allows electrical power to be applied to upper portions 135 cu and 135 du of the comb drives 135 c and 135 d. Upper portions 135 au-135 du and upper portions 140 au-140 du formed from upper layer 184 are upper portions of fixed comb teeth (discussed further below with reference to FIGS. 3A and 3B) of the comb drive systems 135 and 140.

A portion of the upper layer 184 is removed to allow access through the upper layer 184 to an intermediate layer 182, shown in FIG. 2B, for wire bonding to the intermediate layer 182.

FIG. 2B is a plan view of the intermediate layer 182 of the MEMS actuator shown in FIG. 2. Referring to FIGS. 2 and 2B, the movable central structure 110 is coupled to the lower portion 120 i of movable frame structure 120 by the first axis torsional support members 125. The intermediate layer 182 includes the lower portions 130 i of the second axis torsional support members 130, which couple the fixed frame structure 105 to the movable frame structure 120.

Lower portions 135 ai-135 di and lower portions 140 ai-140 di formed from intermediate layer 182 form both movable comb teeth and lower portions of fixed comb teeth (discussed further below with reference to FIGS. 3A and 3B) of the comb drive systems 135 and 140.

In the embodiment of FIG. 1 movable comb teeth of comb drives 35 a-d extend from and are attached to the torsional support members 25. Similarly, movable comb teeth of comb drives 40 a-c extend from and are attached to the torsional support members 30. In the embodiment of FIGS. 2, 2A and 2B, however, movable comb teeth of comb drives 135 a-d extend away from, and are spaced from the torsional support members 125. Similarly, movable comb teeth of comb drives 140 a-d extend away from, and are spaced from the torsional support members 130. Thus, in the embodiment illustrated in FIGS. 2, 2A, and 2B, the torsional support members 125 and 130 are attached at their ends, but not attached to structures along their length. Instead, a gap extends alongside the length of the torsional support members 125 and 130, between the torsional support members 125 and 130 and the comb drives 130 a-d and 140 a-d respectively.

As a result, the embodiment of FIGS. 2, 2A, and 2B allows the width and length of the torsional support members to be selected independent of the comb drive geometry. This allows the torsional spring constant of the torsional support members to be more easily controlled. Further, in embodiments having paired upper and lower torsion members 130 u and 130 i, it allows the width of the torsional support members to be selected so as to facilitate later removal of insulation material between the upper and lower members 130 u and 130 i if desired. Moreover, it allows the comb teeth to extend further from the torsional members to allow greater torque for the device without a concomitant increase in the length of the comb teeth. Limiting the length of the comb teeth inhibits inadvertent contact between the comb teeth that could otherwise occur as a result of excessive length and narrow spacing between the comb teeth. As such, this arrangement also allows closer spacing between adjacent comb teeth to allow greater actuation force to be generated.

FIG. 3A is a partial cross-sectional view of the MEMS actuator shown in FIG. 2 taken through the line A-A. FIG. 3A shows a detailed view of the layered structure of the MEMS actuator 100. The layered structure includes the lower layer 180, the intermediate layer 182, and the upper layer 184. The lower layer 180 and the intermediate layer 182 are separated by a first insulator layer 205. The intermediate layer 182 and the upper layer 184 are separated by a second insulator layer 210. The movable central structure 110 is formed from the intermediate layer 182. The mirrored surface 115 is formed on the movable central structure 110.

It is possible in other embodiments to form the movable central structure 110 from the several layers. For example, it may be formed from the intermediate layer 182 and the upper layer 184 together.

Referring to FIGS. 2A, 2B and 3A, the structure of one of the second axis torsional support members 130 is shown. The second axis torsional support members 130 couple the movable frame structure 120 to the outer fixed frame structure 105. In the example embodiment of FIGS. 2-3A, the second axis torsional support members 130 have a structure that is a paired arrangement. This paired arrangement is used to provide structural support, a torsional restoring force, and routing of electrical signals. More specifically, the paired arrangement includes an upper torsional support member 130 u formed from the upper layer 184 and a lower torsional support member 130 i formed from the intermediate layer 182.

Referring to FIG. 3A, between the lower layer 180 and the lower torsional support member 130 i is a first gap 325 where a portion of the insulator layer 205 has been removed. Between the lower and upper torsional support members 130 i and 130 u is a second gap 327 where a portion of the second insulator layer 210 has been removed. A portion of the first insulator layer 205 and the second insulator layer 210, located between the upper and lower torsional support members 130 u, 130 i, remain at, or near, the fixed frame ends of the torsional support members 130.

In some embodiments, the second gap 325 located between the upper and lower torsional support members 130 u and 130 i can inhibit buckling of the torsional support members 130 that might otherwise occur if insulator material was to remain. For example, some dielectrics introduce residual stress that can cause buckling. Thus, removing some, or all, of the connective dielectric material sandwiched between the upper and lower torsional support members 130 u and 130 i can inhibit buckling.

Ideally, the gaps 325 and 327 should be wide enough to inhibit any shorting between the upper torsional support member 130 u and the lower torsional support member 130 i when they are flexing. A passivation, native oxide, or other insulator layer may be deposited in the gaps 325 and 327 to improve the electrical isolation characteristics between the upper and lower torsional support members 130 u and 130 i.

The paired arrangement of the second axis torsional support members 130 serve both a mechanical and electrical function. In the mechanical context, the paired arrangement provides a means to couple the movable frame structure 120 to the fixed frame structure 105. Moreover, the paired arrangement provides a restoring torsional force that restores the movable frame structure 120 to its original position whenever it is displaced.

In the electrical context, the paired arrangement of the second axis torsional support members 130 is used to route electrical signals across the MEMS actuator 100. Specifically, in one embodiment, each of the upper torsional support members 130 u is a signal line. The upper torsional support member 130 u is used to communicate electrical potential to the comb drives 135 a and 135 b, via the segment 123, while the lower torsional support member 130 i is a separate signal line which provides a different potential that conveniently can be selected as ground potential. Thus, the lower torsional support member 130 i can be conveniently used as a ground path for grounding the movable central structure 110.

In another possible embodiment, the second axis torsional support members 130 are single members. For example, the second axis torsional members may have only members made of upper layer 184 material. This embodiment only includes the upper torsional support member 130 u and does not include the lower torsional support member 130 i. In such an embodiment no ground path is provided for the movable central structure 110 and the movable central structure is electrically floating.

FIG. 3A shows a partial cut away side view along the A-A line of FIG. 2. Illustrated in FIG. 3A is a cut away side view of comb drive 140 b from the second axis comb drive system 140. As shown in FIG. 3A, the comb drive 145 b includes fixed comb stacks 400 and moving combs 410. The moving combs 410, which are formed from the intermediate layer 182, are interdigitated between each of the fixed comb stacks 400. Each of the fixed comb stacks 400 includes an upper fixed comb portion 420 and a lower fixed comb portion 430. The upper fixed comb portion 420 is located directly above the lower fixed comb portion 430, and the two are coupled to each other by a portion of the second insulator layer 210. In certain embodiments, appropriate material selection and/or doping can be used to provide junction isolation between conductive layers rather than providing isolation by using insulator material, if desired.

Thus, the structural arrangement shown in FIG. 2 allows the movable central structure 110 to be moved independently around a first axis and a second axis.

II. Operational Overview

The two-axes electrostatic torsional comb-drive actuator of certain embodiments of the present invention allows a device or structure (such as a mirrored surface) mounted on the movable central structure 110 to be positioned in a wide range of positions. In certain embodiments, the actuator includes a system of comb drives located on opposite sides of torsional support members 125, 130. This comb drive system provides movement about two axes. In particular, the first axis comb drive system 125 provides movement of the movable central structure 110 around the first axis. The second axis comb drive system 140 provides movement of the movable frame structure 120 around the second axis. Moreover, the movable central structure 110 is also moved around the second axis because the movable central structure 110 is coupled to the movable frame structure 120. In this manner, the device or structure mounted on the movable central structure 110 can be accurately positioned in a wide range of positions.

The opposing comb drive arrangement also provides positive and negative rotation about an axis. Thus, using this opposing comb drive arrangement the actuator can be rotated clockwise or counterclockwise about each axis.

As shown in FIG. 3A, the actuator comb drive system includes moving combs 410 interdigitated with fixed comb stacks 400. The moving combs 410 are formed in the intermediate layer 182 and the fixed comb stacks 400 are formed in the upper layer 184 and the intermediate layer 182. The intermediate layer 182 is electrically isolated from the upper layer 184 by the second dielectric layer 210 and the gap 327.

Referring now to FIG. 3B, an electrostatic action is generated by creating an electrical potential differential between the upper fixed combs 420 of the fixed combs stack 400, the intermediate layer 182, and the moving combs 410. This may be accomplished by applying a positive voltage potential to the upper fixed combs 420 while grounding the moving combs 410. The moving combs 410 may be grounded by connecting the bond pad 198 (shown in FIG. 2) to ground. This means that the lower fixed combs 430 of the fixed comb stack 400 and the moving combs 410 are at ground.

FIG. 3B is a partial cross-sectional view of the MEMS actuator shown in FIG. 2 taken through the line A-A and illustrates the movement of the comb drive. The upper fixed combs 420 of the fixed comb stack 400 have a positive charge (as denoted by the “+” symbols in FIG. 3B). The lower fixed combs 430 of the fixed comb stack 400 and the moving combs 410 both are at ground (as denoted by the “−” symbols in FIG. 3B). The lower fixed combs 430 and the upper fixed combs 420 of the fixed comb stack 400 are electrically isolated by the second insulator layer 210 between them. However, the moving combs 410 are free to move, and they are attracted to the upper fixed combs 420 of the fixed comb stack 400. The moving combs 410 move up toward the upper fixed combs 420 thereby providing torsion about their corresponding torsional support members 130.

By way of example, when charged, a comb drive of the first axis comb drive system 135 provides movement around the first axis. Similarly, a comb drive of the second axis comb drive system 140 provides movement around the second axis when charged. Once the electrical power is removed from the upper portion of the fixed combs 420 the attraction between the upper fixed combs 420 and the moving combs 410 ceases. A restoring force is provided by torsional support members such that the moving combs 410 return to their original position, as shown in FIG. 3A.

As discussed above with reference to FIGS. 2A, 2B, and 3A certain embodiments allow independent control around the first and second axes. Thus, if movement is to be provided around the first axis the first axis comb drive system 135 can be used to provide that movement. Decoupled and independent of that movement, the second axis comb drive system 140 can be used to provide movement around the second axis. This independent movement around each axis is achieved by electrically isolating voltage controls of the first axis comb drive system 135 and the second axis comb drive system 140 using the isolated areas. In particular, electrical power can be applied to the first axis comb drive system 135 without the second axis comb drive system 140 receiving any power, and vice versa. This independent comb drive arrangement can allows greater positioning accuracy and control.

Furthermore, as noted above, having comb drives located on either side of each axis allows electrical actuation in both positive and negative rotation about an axis. In addition, in some embodiments, it can allow positional information to be derived such as by capacitive sensing using non-driving comb drives. Moreover, it is possible in some embodiments, to use repulsive actuation potentials to increase actuation response.

The comb-drive electrostatic actuator of FIG. 2 can mitigate the problem of reduced electrostatic force due to large gaps by providing electrostatic action over much smaller gaps. Each comb drive has an array of fixed combs as one of the electrodes and an array of moving teeth as the other electrode. The comb drive is constructed such that the moving comb array is interdigitated between the fixed comb array so that the comb teeth move next to each other rather than toward or away from each other. Thus, certain embodiments can allow improved performance over the pad-type electrostatic actuator.

Further, the above process and structure allows in some embodiments a larger range of motion, it provides the ability to switch an optical signal to a greater number of possible receiving optical fibers. As such, an array of these two-axes optical switches can be employed to handle higher volumes of optical traffic.

III. MEMS Actuator Fabrication

The MEMS actuator is fabricated using a bulk micromachining process. The MEMS actuator is constructed by starting with a layered semiconductor structure. In one embodiment, the layered semiconductor structure is a silicon on insulator (SOI) structure that includes layers of silicon separated by insulator layers located over a substrate. The substrate may be a silicon wafer, or other material such as glass, sapphire, or other substrate material.

In one implementation shown in FIG. 4A, the layered semiconductor structure 600 includes a triple layer of semiconductor material 610, 620, 630. The semiconductor material is used in layers 620 and 630 is selected for both its mechanical properties as well as its electrical properties. The semiconductor material is used to mechanically couple together the components of the MEMS actuator and to route electrical signals to the various electrical components of the MEMS actuator 100, as discussed with reference to FIGS. 2A, 2B, and 3A.

The bulk micromachining fabrication process described herein also includes a self-aligned process that alleviates the registration problem discussed above that is common in vertically actuated comb-drive actuators. This self-aligned process avoids the registration problem by fabricating the comb structure together so as to provide proper alignment between the fixed comb stack and the moving combs.

FIGS. 4A-H is a possible implementation in accordance with the present invention. In general, these processes are performed on the top portion of the layered semiconductor structure and is called the frontside processing. After the frontside processing is performed a protective material process is used to protect the frontside structures before the backside is processed. The backside process is discussed in detail below.

As shown in FIG. 4A, in one implementation the frontside processing is performed using a two semiconductor layers 620 and 630, formed over a substrate 610. The two semiconductor layers 620 and 630, as well as the substrate 610, may be silicon. Thus, in one implementation, a triple-layer silicon structure 600 is formed having a substrate 610, an intermediate semiconductor layer 620, and an upper semiconductor layer 630. A first insulator layer 640 is located between the substrate 610 and the intermediate layer 620. Similarly, insulator layer 650 is located between the intermediate layer 620 and the upper semiconductor layer 630.

As shown in FIG. 4B, a layer 655 is applied to the triple-layer semiconductor structure 600. Layer 655 is used to form a hardmask for etching the comb structure, as well as other structures of the MEMS actuator 100. As such, layer 655 may be oxide, or other suitable hardmask material. After depositing the hardmask material layer 655, the hardmask material layer 655 is patterned using resist, as shown in FIG. 4C. The hardmask material layer 655 is patterned with overwidth fixed comb photoresist masks 660. The overwidth photoresist mask 660 patterns the hardmask material layer 655 wider than the eventual width of the fixed comb teeth. The overwidth photoresist mask 660 is used to etch the hardmask material layer 655 to form overwidth hardmask portions 665 as shown in FIG. 4D. Thereafter, the overwidth photoresist mask is stripped as shown in FIG. 4D.

Turning to FIG. 4E, a second photoresist pattern 670 is used to define the location and width of the fixed and movable comb teeth. The photoresist pattern 670 is formed on the overwidth hardmask portions 665, and on portions of the upper silicon layer 630 between the hardmask portions 665. The overwidth hardmask portions 665 shown in FIG. 4D mitigate misregistration in placement of the resist 670 on the overwidth hardmask portions, while the distance between the fixed and moving comb teeth is set by the mask 670, regardless of mask misregistration.

As shown in FIG. 4F, after the patterning the comb structure with the resist mask 670, the overwidth hardmask portions 665 are etched using the mask 670 to remove excess hardmask material 675. In FIG. 4F, this excess hardmask material 675 is shown in phantom.

Turning to FIG. 4G, after the excess portions 675 of hardmask are removed the comb teeth can be defined in the semiconductor layers below using the resist pattern 670. As shown in FIG. 4G, unmasked portions of the upper semiconductor layer 630 are removed to form the gaps 632 between and adjacent the comb teeth. A deep trench reactive ion etch may be utilized to ensure well defined etch profiles with the hardmask layer 650 acting as an etch stop material for the silicon etch process.

After removing forming gaps 632, the exposed portions 652 of second insulator layer 650 are removed using the resist pattern 670.

Turning to FIG. 4H, after the removal of second insulator portions 652, the resist pattern 670 is stripped. An etch is performed to etch portions 622. Also removed with this etch are the exposed semiconductor portions 633. Typically, the semiconductor layers 620 and 630 will have the same thickness so the semiconductor portions 633 and 622 will complete etching at approximately the same time. Nevertheless, the insulator material below 633 and 622 can be selected to provide an etch stop after removal of portions 633 and 622. The first insulator layer 640 acts as an etch stop that allows deeper etching and higher aspect ratio etching. A high aspect ratio etch such as a deep trench plasma etch or similar high aspect ratio etch may be utilized to ensure well defined etch profiles of the semiconductor material. This allows the height, width, length, and spacing of the comb teeth to be selected to provide a wide range of movement and/or better response times. For example, very tall, narrow, long, and closely spaced combs are possible to allow a wider range of positioning of an actuator.

The processing procedures utilized in FIGS. 4A-4H to define the comb drives 135 and 140 of FIGS. 1, 2A and 2B, also can be employed during comb drive fabrication to define the other silicon and insulator structures of the MEMS actuator 100 discussed above with reference to FIGS. 2A and 2B.

Although in the comb drive actuator embodiment of in FIGS. 2A-3B, the taller stacked comb teeth are the fixed comb stacks 400 and the shorter comb teeth are the moving combs 410, it is possible in other embodiments to reverse this arrangement and provide the shorter comb teeth as fixed comb teeth and the taller comb teeth as moving comb teeth.

After the comb structure has been defined as illustrated in FIGS. 4A-H, the exposed semiconductor surface may be passivated (not shown). Also, after defining the comb structure and other structures, the mirror or other device is formed on the central movable structure. For example, a composite Ti/Pt/Au mirror may be formed on the central movable structure. Furthermore, as discussed further below, a back side etch may be performed to remove portions of substrate material 610 and portions first insulator layer 640 under the combs.

In this implementation of FIGS. 4A-4H, the comb structure remains and is self-aligned because of the pattern created using the top insulator layer 655 and the resist 670. Because the same pattern is used to define the fixed comb stacks and the moving combs, the registration problem is eliminated. The width and spacing of the entire height of the fixed comb stacks and the moving combs are defined using a single photoresist mask.

In the implementation of FIGS. 4A-4H, the combs are not subject to residual stress due to multi-step comb material deposited layers that can cause some of the combs to be physically skewed to one side or another. When this occurs, the comb will be attracted to one side more that the other, causing instability. By way of example, if the fixed combs were etched in a prior step and then the moving combs were etched later, residual stress could cause the moving combs to be skewed to one side. This means that a moving comb located between two fixed combs would be closer to one fixed comb that the other. When an electrostatic force was applied, the skewed moving comb would be located to the closer fixed comb more than the other fixed comb, thereby causing instability. This registration problem is an inherent problem with conventional vertically actuated comb-drive actuators.

Fabrication of the fixed comb stacks and the moving combs are created with the above self-aligned process avoids the problems otherwise associated with conventional fixed and moving combs fabrication. This decreases the probability that damage to the combs will occur during fabrication or during operation and thus increases yield and reliability.

FIG. 5A illustrates a cross section of portions of two MEMS devices 700 and 705. FIG. 5A shows a mirrored surface 715 is located on top of the bottom semiconductor layer 620. A first gap 720 between the substrate layer 610 and the intermediate semiconductor layer 620 may be formed during the frontside processing discussed above reference to FIGS. 4A-4H. This can be accomplished allowing the etch of the first insulator layer 640 to undercut the intermediate semiconductor layer 620. A second gap 725 also was created between the intermediate semiconductor layer 620 and the upper semiconductor layer 630 by removing a portion of the second insulator layer 650 therebetween. Similarly, this can be accomplished allowing the etch of the second insulator layer 640, discussed above, to undercut the intermediate semiconductor layer 620.

Although not shown in FIGS. 5A-5H, a passivation layer, such as an oxide layer (not shown) typically is formed on the front side exposed semiconductor surfaces during front side processing.

The gap 725 is created to inhibit buckling of between the torsional support members 730 i and 730 u during torsion. If there is any oxide left between the torsional support members buckling possibly could occur in certain embodiments. If the torsional support members buckle the combs are no longer self-aligned and become skewed. Thus, in some embodiments, the gap 725 between the torsional support members 730 i and 730 u inhibits buckling to improve robustness of the actuator 100.

In certain implementations, a backside process is used. The backside process can include providing a cavity behind moving structures of MEMS devices 700 and 705 such as the central movable structure 710 and comb drives (not shown in this cross-section) to allow their movement. Furthermore, as will be discussed further below, and in U.S. patent application Ser. No. 10/020,050 filed Dec. 13, 2001, by Wang et al., entitled LOW DEFECT METHOD FOR DIE SINGULATION AND FOR STRUCTURAL SUPPORT FOR HANDLING THIN FILM DEVICES, issued as U.S. Pat. No. 6,573,156, on Jun. 3, 2003, herein incorporated by reference in its entirety, self dicing of MEMS devices can be accomplished. AS illustrated, it may be accomplished by providing a cut or groove 755 between the first MEMS device 700 and the second MEMS device 705 during front sice processing in conjunction with backside processes.

As shown in FIG. 5B, a protective material 735 is applied to the front side structures prior to backside processing. The protective material 735 may be a conformal material which deposits into the gaps between and around the structures of the MEMS devices 700 and 705 (including the comb drives, the torsional support members, and gaps between devices). In part, the protective material 735 protects the structures and surfaces of the MEMS devices 700 and 705 during backside processing.

Any type of protective material may be used in this process, such as for example photoresist. With smaller geometries, however, pockets of air can inhibit photoresist completely surrounding the structures. Thus, photoresist does not always work well on smaller geometries because the photoresist cannot reach each cavity of the MEMS devices 700, 705. Epoxy may also be used as the protective material, but epoxies can sometimes present problems with completely filling small cavities.

In certain implementations the protective material is selected so as to allow dry or vapor phase deposition, and dry phase removal of the protective material. This can help avoid surface tension effects and solvents which could otherwise contribute to formation of voids or cause stresses on the structures.

In one implementation, the protective material is parylene. Parylene is an extremely conformal material. Parylene may be deposited from vapor phase into cracks and crevices of the MEMS structure and leaves substantially no voids at the depositing surface.

As shown in FIG. 5C, in certain implementations, after the protective material 735 has been applied, an optional carrier wafer 740 is attached to the front side of the triple-layer semiconductor structure 600. The carrier wafer 740 may be applied with a bonding agent, such as resist. The carrier wafer 740 facilitates handling of the triple-layer semiconductor structure 600 for processing. While the triple-layer semiconductor structure 600 is inverted for backside processing, the protective material 735 serves to hold pieces of the MEMS devices 700, 705 together and also provides protection to any exposed parts.

The triple-layer semiconductor structure 600 then is patterned with resist 745 placed on the substrate semiconductor layer 610, as shown in FIG. 5D. Next, as shown in FIG. 5E, the substrate layer 610 is patterned and etched to remove portions of the substrate layer 610 under movable structures, such as the central movable structure, or the comb drives (not shown) of the MEMS device. Thereafter, the resist 745 and the exposed portions of the first insulator layer 640 are removed.

FIG. 5E also shows that the groove 755 etched between the first MEMS device 700 and the second MEMS device 705 is now joined to groove 757 etched from the backside of the substrate 610. Thus, after processing the grooves 755 and 757 completely separate the first MEMS device 700 and the second MEMS device 705, which are held together only by the protective material 735 and the carrier wafer 740. As the parylene is removed, the MEMS devices separate, already diced and separated. This self-dicing process can prevent damage and debris contamination that can be caused by traditional mechanical dicing tools.

Referring to FIG. 5E, although not shown, in some implementations, it is possible to fabricate a mirror or other device on the back side 710 b of the central movable structure 710 instead of, or in addition to the mirror 715 shown on the front side. Further, in other implementations not shown in FIG. 5E, it is possible to etch a portion of the movable central structure 710 to reduce its mass. For example, a portion of the back side surface 710 b may be etched to hollow out the movable central structure 710. Reducing the mass of the movable central structure 710 can improve actuation response. Further in some implementations, the movable central structure 710 may be provided with a honeycomb, channeled, cross-hatched, or other pattern to reduce mass while providing structural strength.

As shown in FIG. 5F, the carrier wafer 740 then is removed. Next, as shown in FIG. 5G the protective material 735 then is removed from the entire structure. In the case of parylene, an oxygen plasma asher, or other suitable apparatus may can be used to remove the parylene. Dry removal of the protective material 735 helps minimize damage to fragile structures, which could otherwise result from wet removal processes. Further, a dry removal process can limit contamination that otherwise might be associated with wet removal processes. Removing the parylene dices MEMS devices without requiring sawing, scoring, cutting, grinding, or other similar separation techniques.

IV. Additional Embodiments

FIGS. 6-21 show simplified illustrations of MEMS devices in accordance with certain embodiments of the present invention. The vertical comb drives illustrated in the embodiments of FIGS. 6-21 can have tall and short comb teeth as discussed above with reference to FIGS. 2-4H. Thus, although not shown, it is understood that the embodiments of FIGS. 6-14 include multiple layers in accordance with the above description.

FIGS. 6 & 7 show simplified illustrations of single axis actuators 1600 and 1700, respectively. The single axis actuator 1600 has two torsional flexible members 1625. The single axis actuator 1600 of FIG. 6 is shown with a comb drive portion 1635 a adjacent one of torsional members 1625 and a comb drive portion 1635 b adjacent one of the torsional members 1625. Comb drive portions 1635 a and 1635 b are located on opposite sides of the torsional members 1625. Shown in FIG. 7, the single axis actuator 1700 has a single torsional member 1725. Comb drive portions 1735 a and 1735 b are located on opposite sides of the single torsional member 1725. Although in FIGS. 6 & 7 the comb drives 1635 and 1735 are shown extending directly from the torsional members 1625 and 1725, respectively, it is understood that the comb drives 1635 and 1735 may be spaced from the torsional members by a gap as shown in FIG. 2.

FIG. 8 shows a simplified illustration of a single axis diving board type actuator 1800. A movable structure 1810 is flexibly coupled at 1825 to a support structure 1805. It is possible to use a torsional member (not shown) to flexibly couple the movable structure 1810 to the support structure 1805. A vertical comb drive 1835 extending laterally away from the end of the movable structure causes actuation of the movable structure 1810.

FIG. 9 shows a simplified illustration of a piston type actuator 1900. A movable structure 1910 spans a support structure 1905 and is flexibly supported at its ends 1925 to the support structure 1905. The comb teeth of the vertical comb drive 1905 extend laterally from the sides of the movable structure and cause actuation of the movable structure 1910 into or out of the page.

FIG. 10 shows a simplified illustration of a multiple diving board actuator 10000. Movable structures 10010 a and 10010 b are flexibly coupled to a support structure 10005 at 10025 a and 10025 b respectively such that the ends of the movable structures 10010 a and 10010 b are adjacent. The movable structures 10010 a and 10010 b are actuated with vertical comb drives 10035 a and 10035 b respectively. The movable structures 10010 a and 10010 b may be actuated together, or separately if desired.

FIG. 11 shows a simplified illustration of a two axes actuator 11000. The actuator 11000 has a movable central structure 11010 flexibly coupled to a movable frame 11020 via torsional members 11025. The movable central structure 11010 is actuated about the torsional members 11025 using comb drive 11035. Vertical comb drives 11040 actuate the movable central structure 11010 and the movable frame 11020 about torsional members 11030. The vertical comb drives 11040 provide bidirectional rotation of the movable central structure 11010 about the torsional members 11030, while the comb drive 11035 provides a unidirectional rotation

FIG. 12 shows a simplified illustration of a two axes actuator 12000 having comb drives 12035 extending from a central portion of the movable central structure 12010. The comb drives 12035 actuate the central movable structure 12010 about torsional members 12025. In this embodiment, the comb drives 12035 are located at a periphery of the movable central structure 12010, remote from the torsional members 12025 and distal from the axis defined by torsional members 12025. Such an embodiment may be employed to provide high force for lower angles of movement of the movable central structure 12010. Thus, distal comb drives 12035 capable of generating high torque can be used in conjunction with high restoring force torsional members 12025 if desired.

FIG. 13 shows a simplified illustration of a two axes actuator 13000 having comb drives 13035 extending from a central portion of the movable central structure 13010. The comb drives 13035 actuate the central movable structure 13010 about torsional members 13025. In this embodiment, the comb drives 13035 are located at a periphery of the movable central structure 13010, remote from the torsional members 13025 and distal from the axis defined by torsional members 13025. Furthermore, in this embodiment, the comb drives 13040 have movable comb teeth extending from a periphery of the movable frame 13020, and the torsional members 13030 extend from a periphery of the movable frame 13020 but are located outside of the comb drives in a non-interposed relationship with the comb drives 13040.

FIG. 14 is a simplified illustration of a two axes actuator 14000. The comb drives 14035 extend from a central portion of the movable central structure 14010. The comb drives 14035 actuate the central movable structure 14010 about torsional members 14025. In this embodiment, the comb drives 14035 are located at a periphery of the movable central structure 14010, remote from the torsional members 14025 and distal from the axis defined by torsional members 14025. In this embodiment, the comb drive 14035 has a larger span than the central movable structure 14010. In this embodiment, the entire movable structure 14010 as well as the torsional members 14025 are interposed between complimentary portions 14035 a and 14035 b of the comb drives 14035.

Referring to FIG. 14, comb drives 14040 are spaced apart from the torsional members 14030 with the torsional members 14030 being interposed between complimentary portions 14040 c and 14040 d of the comb drives 14040. Such an embodiment may be employed to generate high torsional forces. The comb drives 14040 can have a larger span than the central movable structure 14010 to allow a larger number of comb teeth for high force or low voltage applications.

As shown in FIG. 14, spurs 14023 and 14033 may be provided near the torsional members 14025 and 14030. Spurs may be provided in embodiments where the comb drives 14030 or 14040 are spaced far from the torsional members 14030 or 14040, respectively. The spurs such as 14023 and 14033 may be provided to assist in controlling the etch process of high profile narrow structures that would not otherwise have nearby structures.

FIG. 15 shows a simplified illustration of a double angle, co-axial comb drive actuator 15000. In the embodiment of FIG. 15, inner torsional members 15025 coupled between the movable central structure 15010 and the movable frame 15020, lie along the same axis as outer torsional members 15030 which are coupled between the movable frame 15020 and a support structure (not shown). Thus, the total rotation of the movable central structure 15010 is the sum of the rotations caused by inner and outer comb drives 15035 and 15040. In some embodiments such a configuration can be utilized to extend the rotation angle of the central movable structure 15010.

There is a tradeoff between the comb drive force and the maximum scanning angle. For the same comb finger thickness, larger scanning angle can be achieved with shorter finger length. However, the driving force will be reduced at the same time. In order to increase the scanning angle with the similar voltage, this double angle, co-axial comb drive structure can be used to double the scanning angle with the same driving voltage and still maintain the same spring design. For example, a 45 degree tilted mirror with scanning capability can be achieved with this concept, if each ring can scan 22.5 degrees.

This concept is not limited to double angles. It can be implemented with triple angles or more. FIG. 16 shows a simplified illustration of a triple angle, co-axial actuator 16000. In the embodiment of FIG. 16, upper conductor is formed so that the comb drives 16040, 16037, and 16035 may be operated together to at least triple the angle of rotation of the movable central structure 16010. As discussed above the comb drives 16040, 16037, or 16035, or the torsional support members 16025, 16027, or 16030 may have the same or different operating characteristics. A 90 degree vertical mirror can be realized with this multiple co-axial angle concept, if four co-axial comb drives are utilized each producing a 22.5 degree scanning angle. This vertical mirror can be configured as and N×N cross-bar switch, on/off switch, an optical add/drop switch, etc. It should be noted that multiple angle concept is not limited to single axis structures. This large scanning angle concept can be implemented in independent two-axis scanners.

FIGS. 17 & 18 show simplified illustrations of two axes, single direction actuators 17000 and 18000. Shown in FIG. 17, the movable central structure 17010 is rotated about torsional support members 17025 with comb drive 17035. Comb drive 17040 is used to rotate the movable frame 17020 and the movable central 17010 about torsional members 17030. The ends of the torsional support members 17030 are mounted to a fixed support structure (not shown). The fixed comb teeth 17040 f of comb drive 17040 are mounted to a fixed support structure 17050.

In FIG. 18 the movable central structure 18010 is rotated about torsional support members 18025 with comb drive 18035. Comb drive 18040 is used to rotate the movable frame 18020 and the movable central 18010 about torsional members 18025. In this embodiment, the movable frame 18020 does not completely surround the movable central structure 18010. The ends of the torsional support members 18030 are mounted to a fixed support structure (not shown). The fixed comb teeth 18040 f of comb drive 18040 are mounted to a fixed support structure (not shown).

FIG. 19 shows a simplified illustration of a segmented actuator 19000. Comb drive 19040 a rotates a movable structure 19010 about torsional support members 19030 a. In this embodiment, the comb teeth 19040 af are fixed with respect to the frame 19020 a and the comb teeth 19040 am are movable with respect to the frame 19020 a. Comb drive 19040 b rotates the frame 19020 a about torsional support members 19030 b. Rotation of the frame 19020 a about the torsional support members 19030 b also rotates the movable central structure 19010 about the torsional members 19030 b. Comb drive 19040 c rotates the frame 19020 b about torsional support members 19030 c. The frame 19020 c may be mounted to a substrate as a fixed frame, or the frame 19020 c may be another link in a continuing chain of the segmented actuator 19000. In this embodiment, application of a signal at V₁ supplies the signal to all comb drives 19040 a, 19040 b, and 19040 c.

FIG. 20 shows a simplified illustration of a vertical comb drive device 20000 having a vertical movable structure 20010. In this embodiment, the comb drive 20040 causes rotation of the movable structure 20010 about the torsional support members 20030. Capacitive type actuator pads 20041 may be used to steer the movable structure 20010 and frame 20020 using a flexible cantilever beam type bending spring 20021. Thus, the comb drive 20040 actuates the movable structure into or out of the paper, while actuator pads 20041 actuate the movable structure 20010 and frame 20020 side-to-side. A device or structure (not shown) may be located at the surface 20010 a of the movable structure 20010. Further, the movable structure 20010 may include a portion of the substrate (not shown), if desired.

In the embodiment of FIG. 21, a linear comb drive 21041 with concentric comb teeth can be used to steer the movable structure 21010 side-to-side. Thus, the vertical comb drive 21040 causes rotation of the movable structure 21010 about the torsional support members 21030 and the linear comb drive 21041 is steers the movable structure 21010 and frame 20020 using the flexible cantilever beam type bending spring 21021.

It should be noted that although discussed with respect to actuation of the movable structures, certain implementations may be used as sensors to capacitively sense the movement of the movable structures. For example, the comb drives could be used to generate capacitive signal to sense the position, acceleration, or actuation movement of the movable structure in response to external static or dynamic forces applied to the movable structure.

The foregoing description has been presented for the purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed. Many modifications and variations are possible in light of the above teaching. It is intended that the scope of the invention be limited not by this detailed description of the invention, but rather by the claims appended hereto. 

1. A MEMS device comprising: A) a movable structure comprising two shaft portions, defining a first shaft portion and a second shaft portion, extending in opposite directions, B) a movable frame comprising two shaft portions, defining a third shaft portion and a fourth shaft portion, extending in opposite directions, C) a first set of two torsional members, co-aligned with each other, each of said two torsional members connecting the movable structure to the movable frame and passing through at least a portion of one of said first or second shaft portions such that the movable structure is capable of rotation about a first axis defined by the first set of two torsional members, D) a first set of at least four vertical comb drives, each vertical comb drive defining a plurality of stationary comb teeth extending from said movable frame and a plurality of movable comb teeth extending from said movable structure, two of which vertical comb drives are electrostatically coupled to one of said first and second shaft portions and two of which are each electrostatically coupled to the other of said first and second shaft portions, E) an outer fixed frame structure, F) a second set of two torsional members co-aligned with each other, each of said two torsional members connecting the movable frame to the support structure and passing through one of the two shaft portions extending from the movable frame such that the movable frame is capable of rotation about a second axis defined by the second set of two torsional members, and G) a second set of at least four vertical comb drives, each vertical comb drive defining a plurality of stationary comb teeth extending from said outer fixed frame structure and a plurality of movable comb teeth extending from said movable frame, two of which vertical comb drives are electrostatically coupled to one of said third and fourth shaft portions and two of which are coupled to the other of said third and fourth shaft portions; wherein said movable structure, said movable frame, said first set of two torsional members, said first set of at least four comb drives, said outer fixed frame structure, said second set of two torsional members, said second set of at least four comb drives are all fabricated from a single multi-layer semi-conductor structure of semiconductor material and insulator material using a single mask to define, during a series of processing steps, the location and width of both movable comb teeth and stationary comb teeth so as to assure self alignment of the comb teeth of the first and second sets of vertical comb drives, wherein said multi-layer semi-conductor structure is comprised of at least two silicon layers, defining an upper semi-conductor layer and an intermediate semi-conductor layer, and at least one additional semiconductor layer, defining a bottom layer, said top layer, said intermediate layer and said bottom layer being separated by at least two insulator layers defining a first lower insulator layer and a second intermediate insulator layer, portions of said second intermediate insulator layer separating said stationary comb teeth into first electric potential regions and second electric potential regions and other portions of said second intermediate insulator layer being removed to define a top surface of said movable comb teeth, wherein a hardmask material is applied to the upper semi-conductor layer and etched utilizing a first photoresist pattern to form overwidth hardmask portions for etching the stationary comb teeth, wherein a second photoresist pattern is formed on the overwidth hardmask portions to define location and a cross section of the stationary comb teeth and on portions of the upper semi-conductor layer between the overwidth hardmask portions to define location and a cross section of the movable comb teeth to define distances between the fixed and movable comb teeth, wherein excess portions of the overwidth hardmask portions are removed utilizing the second photoresist pattern and then the unmasked portions of the upper semi-conductor layer is etched away utilizing the same second photoresist pattern forming deep gaps in the upper semi-conductor layer with the upper insulator layer acting as an etch stop material for the upper semi-conductor layer etch to define exposed portions of the upper insulator layer, and then the exposed portion of the upper insulator layer is removed utilizing the same second photoresist pattern; wherein after removal of the exposed portion of the upper insulator layer, the second photoresist pattern is removed and exposed portions of the upper semiconductor layer and the exposed portions of the second semiconductor layer are etched away down to the first lower insulator layer to define the stationary comb teeth comprising portions of the first semiconductor layer and the second semiconductor layer separated by portions of the second intermediate insulator layer and to define the movable comb teeth comprising portions of the intermediate semiconductor layer with vertical gaps between the teeth; and wherein a backside etch is performed to etch portions of the bottom layer and the first lower insulator layer to permit the movable teeth to move relative to the stationary teeth.
 2. A MEMS device as in claim 1 wherein said first and second torsional members are aligned orthogonally to said third and fourth torsional members.
 3. A MEMS device as in claim 1 wherein each of said third and fourth torsional members comprise an upper member and a lower member separated from each other along sections of the upper and lower members.
 4. A MEMS device as in claim 1 wherein said movable frame comprises an upper portion and a lower portion separated by an insulator portion wherein the upper portion is electrically separated into two segments defining a first segment and a second segment.
 5. A MEMS device as in claim 4 wherein said first segment is adapted to provide electric power to one of the two comb drives coupled to the first shaft portion and one of the two comb drives coupled to the second shaft portion and the second segment is adapted to provide electric power to the other of the two comb drive coupled to the first shaft portion and the other of the two comb drive coupled to the second shaft portion.
 6. A MEMS device as in claim 1 wherein deep trench reactive ion etch is utilized to etch both the upper semi-conductor layer and the intermediate semi-insulator layer to ensure well defined etch profiles with said hard mask layer acting as an etch stop material for the silicon etch process.
 7. A process for fabricating a MEMS device comprising: A) a movable structure comprising two shaft portions, defining a first shaft portion and a second shaft portion, extending in opposite directions, B) a movable frame comprising two shaft portions, defining a third shaft portion and a fourth shaft portion, extending in opposite directions, C) a first set of two torsional members, co-aligned with each other, each of said two torsional members connecting the movable structure to the movable frame and passing through at least a portion of one of said first or second shaft portions such that the movable structure is capable of rotation about a first axis defined by the first set of two torsional members, D) a first set of at least four vertical comb drives, each vertical comb drive defining a plurality of stationary comb teeth extending from said movable frame and a plurality of movable comb teeth extending from said movable structure, two of which vertical comb drives are electrostatically coupled to one of said first and second shaft portions and two of which are each electrostatically coupled to the other of said first and second shaft portions, E) an outer fixed frame structure, F) a second set of two torsional members co-aligned with each other, each of said two torsional members connecting the movable frame to the support structure and passing through one of the two shaft portions extending from the movable frame such that the movable frame is capable of rotation about a second axis defined by the second set of two torsional members, and G) a second set of at least four vertical comb drives, each vertical comb drive defining a plurality of stationary comb teeth extending from said outer fixed frame structure and a plurality of movable comb teeth extending from said movable frame, two of which vertical comb drives are electrostatically coupled to one of said third and fourth shaft portions and two of which are coupled to the other of said third and fourth shaft portions; wherein said movable structure, said movable frame, said first set of two torsional members, said first set of at least four comb drives, said outer fixed frame structure, said second set of two torsional members, said second set of at least four comb drives are all fabricated from a single multi-layer semi-conductor structure of semiconductor material and insulator material using a single mask to define, during a series of processing steps, the location and width of both movable comb teeth and stationary comb teeth so as to assure self alignment of the comb teeth of the first and second sets of vertical comb drives, and wherein said multi-layer semi-conductor structure is comprised of at least two silicon layers, defining an upper semi-conductor layer and an intermediate simi-conductor layer, and at least one additional semiconductor layer, defining a bottom layer, said top layer, said intermediate layer and said bottom layer being separated by at least two insulator layers defining a first lower insulator layer and a second intermediate insulator layer, and wherein said process of fabricating said MEMS device comprises the steps of: A) applying a hardmask material to the upper semi-conductor layer and etching the hardmask material utilizing a first photoresist pattern to form overwidth hardmask portions for etching the stationary comb teeth, B) forming a second photoresist pattern on the overwidth hardmask portions to define location and a cross section of the stationary comb teeth and on portions of the upper simi-conductor layer between the overwidth hardmask portions to define location and a cross section of the movable comb teeth and to define distances between the fixed and movable comb teeth, C) removing excess portions of the overwidth hardmask portions utilizing the second photoresist pattern and then etching away the unmasked portions of the upper semi-conductor layer utilizing the same second photoresist pattern forming deep gaps in the upper semi-conductor layer with the upper insulator layer acting as an etch stop material for the upper semi-conductor layer etch to define exposed portions of the upper insulator layer, and then removing the exposed portion of the upper insulator layer utilizing the same second photoresist pattern; D) after removal of the exposed portion of the upper insulator layer, removing the second photoresist pattern and exposed portions of the upper semiconductor layer and etching away the second semiconductor layer to define (i) the stationary comb teeth comprising portions of the first semiconductor layer and the second semiconductor layer separated by portions of the second intermediate insulator layer and (ii) the movable comb teeth comprising portions of the intermediate semiconductor layer with vertical gaps between the teeth; and E) performing a backside etch to etch portions of the bottom layer and the first insulator layer to permit the movable teeth to move relative to the stationary teeth.
 8. A process as in claim 7 wherein deep trench reactive ion etch is utilized to etch both the upper semi-conductor layer and the intermediate semi-insulator layer to ensure well defined etch profiles with said hard mask layer acting as an etch stop material for the silicon etch process. 